Rapid mobilization of ferritin iron by ascorbate in the presence of oxygen

L-(—)-ascorbate mobilizes iron from horse-spleen ferritin in the presence of oxygen at pH 8.0. The reaction is strongly stimulated by Cu²⁺. Dehydroascorbate and other stable oxidation products of ascorbate are ineffective. We present evidence that monodehydroascorbate mobilizes ferritin iron by reduction.     

Photochemical mobilization of ferritin iron

The release of Fe from horse spleen ferritin through photochemical reduction of Fe³⁺ to Fe²⁺ was studied in vitro. Spectrophotometric measurement of the Fe(Ferrozine)₃ ^4– complex (specific for Fe²⁺) was used to quantify rates of Fe²⁺ mobilization. Light radiation from cool white fluorescent plus incandescent bulbs effectively promoted the rate of Fe²⁺ release. Compounds known to be present in plants provided further regulation of photorelease. Reductive removal from ferritin was inhibited by phosphate, and hydroxide, whereas citrate, oxalate, tartrate, and caffeate enhanced the release. Of the organic acids studied, caffeate was the only compound which induced detectable Fe²⁺ mobilization in the absence of irradiation. Rate constants for photorelease ranged from 2.7×10^–3 sec^–1 (pH=4.6) to 2.1×10^–3 sec^–1 (pH=7.1) at 26.5°C. These findings provide one possible explanation for the low level of ferritin-Fe in healthy, illuminated plant tissue.     

Ferroportin-mediated mobilization of ferritin iron precedes ferritin degradation by the proteasome

Ferritin is a cytosolic molecule comprised of subunits that self-assemble into a nanocage capable of containing up to 4500 iron atoms. Iron stored within ferritin can be mobilized for use within cells or exported from cells. Expression of ferroportin (Fpn) results in export of cytosolic iron and ferritin degradation. Fpn-mediated iron loss from ferritin occurs in the cytosol and precedes ferritin degradation by the proteasome. Depletion of ferritin iron induces the monoubiquitination of ferritin subunits. Ubiquitination is not required for iron release but is required for disassembly of ferritin nanocages, which is followed by degradation of ferritin by the proteasome. Specific mammalian machinery is not required to extract iron from ferritin. Iron can be removed from ferritin when ferritin is expressed in Saccharomyces cerevisiae, which does not have endogenous ferritin. Expressed ferritin is monoubiquitinated and degraded by the proteasome. Exposure of ubiquitination defective mammalian cells to the iron chelator desferrioxamine leads to degradation of ferritin in the lysosome, which can be prevented by inhibitors of autophagy. Thus, ferritin degradation can occur through two different mechanisms.     

Arsenic species that cause release of iron from ferritin and generation of activated oxygen

The in vitro effects of four different species of arsenic (arsenate, arsenite, monomethylarsonic acid, and dimethylarsinic acid) in mobilizing iron from horse spleen ferritin under aerobic and anaerobic conditions were investigated. Dimethylarsinic acid (DMA(V)) and dimethylarsinous acid (DMA(III)) significantly released iron from horse spleen ferritin either with or without the presence of ascorbic acid, a strong synergistic agent. Ascorbic acid-mediated iron release was time-dependent as well as both DMA(III) and ferritin concentration-dependent. Iron release from ferritin by DMA(III)) alone or with ascorbic acid was not significantly inhibited by superoxide dismutase (150 or 300 units/ml). However, the iron release was greater under anaerobic conditions (nitrogen gas), which indicates direct chemical reduction of iron from ferritin by DMA(III), with or without ascorbic acid. Both DMA(V) and DMA(III)) released iron from both horse spleen and human liver ferritin. Further, the release of ferritin iron by DMA(III)) with ascorbic acid catalyzed bleomycin-dependent degradation of calf thymus DNA. These results indicate that exogenous methylated arsenic species and endogenous ascorbic acid can cause (a) the release of iron from ferritin, (b) the iron-dependent formation of reactive oxygen species, and (c) DNA damage. This reactive oxygen species pathway could be a mechanism of action of arsenic carcinogenesis in man.     

Studies on the mobilization of iron from ferritin by isolated rat liver mitochondria.

Rat liver mitochondria and rat liver mitoplasts mobilize iron from ferritin by a mechanism which depends on a respiratory substrate (preferentially succinate), a small molecular weight electron mediator (FMN, phenazine methosulphate or methylene blue) and (near) anaerobic conditions. The release process under optimized conditions (approx. 50 mumol/1 FMN, 1 mmol/l succinate, 0.35 mmol/1 Fe(III) (as ferritin iron), 37 degrees C and pH 7.40) amounts to 0.9--1.2 nmol iron/mg protein per min. The results suggest that ferritin might function as an intermediate in the cytosolic transport of iron to the mitochondria.     

Reduction of exogenous flavins and mobilization of iron from ferritin by isolated mitochondria

The release mechanism for ferritin iron and the nature of the compound(s) which donate iron to the mitochondria are two important problems of intracellular iron metabolism which still await their solution. We have previously shown that isolated mitochondria reduce exogenously added flavins in a ubiquinol-flavin oxidoreductase reaction at the C-side of the inner membrane and that the resulting dihydroflavins function as reductants in mitochondrial mobilization of iron from ferritin (Ulvik, R. J., and Romslo, I. (1981). Biochim. Biophys. Acta 635, 457-469). In the present study it is shown that the rate at which iron is removed from ferritin depends on the capability of the flavins to penetrate (1) the mitochondrial outer membrane and (2) the intersubunit channels of the ferritin protein shell. Intact mitochondria reduce flavins at rates which decrease in the following order: riboflavin > FAD > FMN. The ferritin iron mobilization rates decrease in the order of riboflavin > FMN > FAD. The results are further support for the operation of a flavin-dependent mitochondrial ferrireductase, and strengthen the suggested role for ferritin as a donor of iron to the mitochondria.     

Separation of lipoamide dehydrogenase isoenzymes by affinity chromatography.

1. Lipoamide dehydrogenase NADH: lipoamide oxidoreductase, (EC 1.6.4.3) from pig heart has been separated into two sets of isoenzymes by chromatography on lipoyl- and NAD+-derivatized Sepharose-4B matrices. The first fraction is eluted at 30 mM sodium phosphate buffer (pH 7.2), the other requires a higher ionic strength. The two groups originate from the alpha-ketoglutarate and the pyruvate dehydrogenase complex respectively. 2, Hydrophobic chromatography on a homologous series of alkyl-Sepharoses lead to similar results. The first fraction is eluted with 30 mM phosphate buffer in the case of propyl- and butyl-Sepharose but a high ionic strength is required in the case of an increased chain length (C5--C6). The second fraction is reversibly bound on Sepharose-NC3 and -NC4 but binding becomes irreversible at higher chain lengths. 3. Aminoalkyl-Sepharose behave qualitatively as the alkyl derivatives although elution, particularly in the case of the second fraction, can be realized at lower ionic strength. 4. Matrices which are negatively charged (Sepharose-NCnCOOH, n equal 3--7) have no affinity at pH 7.2. 5. The influence of a neutral polar substituent has been studied by comparing the following matrices: Sepharose-NC6OH, Sepharose-NC6NH2 and Sepharose NC6. Binding of the various isoenzymes is completely reversible in the case of a Sepharose-NC6OH matrix and the elution behaviour is identical to that on propyl- and butyl matrices.     

Modification of pig heart lipoamide dehydrogenase by cupric ions.

The insertion of a second disulfide bridge into native pig heart lipoamide dehydrogenase, requires two Cu-2+ ions for each catalytic center inactivated under anaerobic conditions. During inactivation, both metal atoms become reducible by their juxtaposition to the two participating cysteine residues and may be removed as the Cu+-chelates of neocuproine and bathocuproinesulfonate, leaving an additional disulfide bridge on the protein. Inactivation does not require the presence of oxygen, but when substoichiometric levels of copper are used under aerobic conditions the slow regeneration of Cu-2+ becomes rate-limiting. The course of aerobic inactivation is markedly biphasic at 0 degrees using 2 Cu-2+/FAD, with 30% of the total change completed rapidly, followed by a much slower phase. Both the extent of the fast phase and the rate of the second phase are enhanced by increasing levels of Cu-2+, but are relatively unaffected when the Cu-2+/FAD ratio is maintained at 2 and the protein concentration is varied. The enzyme affords several binding sites for Cu-2+ at pH 7.8, and it is suggested that competition between these sites during the initial statistical distribution of metal ions may explain this biphasic behavior.     

Nitroreductase activity of heart lipoamide dehydrogenase.

A novel reaction catalysed by lipoamide dehydrogenase is described. In the presence of NADH, lipoamide dehydrogenase reduces the nitro group of 4-nitropyridine and 4-nitropyridine N-oxide. The elution profiles from a DEAE-cellulose column for the dehydrogenase and nitroreductase activities are identical. Chemical modifications of critical amino acid residues suggest that the two activities share a common catalytic domain. Nitro reduction catalysed by lipoamide dehydrogenase was monitored spectrophotometrically and chromatographically. The major product from the enzymic reduction of 4-nitropyridine was isolated and characterized structurally as NN-bis(pyridinyl)hydroxylamine, which is formed presumably via 4-hydroxyaminopyridine in a four-electron redox reaction.     

Studies on the mobilization of iron from ferritin by isolated rat liver mitochondria

Rat liver mitochondria and rat liver mitoplasts mobilize iron from ferritin by a mechanism which depends on a respiratory substrate (preferentially succinate), a small molecular weight electron mediator (FMN, phenazine methosulphate or methylene blue) and (near) anaerobic conditions.The release process under optimized conditions (approx. 50 μmol/l FMN, 1 mmol/l succinate, 0.35 mmol/l Fe(III) (as ferritin iron), 37°C and pH 7.40) amounts to 0.9–1.2 nmol iron/mg protein per min.The results suggest that ferritin might function as an intermediate in the cytosolic transport of iron to the mitochondria.     

Reduction of ubiquinone by lipoamide dehydrogenase. An antioxidant regenerating pathway.

Lipoamide dehydrogenase belongs to a family of pyridine nucleotide disulfide oxidoreductases and is ubiquitous in aerobic organisms. This enzyme also reduces ubiquinone (the only endogenously synthesized lipid-soluble antioxidant) to ubiquinol, the form in which it functions as an antioxidant. The reduction of ubiquinone was linear with time and exhibited turnover numbers of 5 and 1.2 min(-1) in the presence and absence of zinc, respectively. The reaction was stimulated by zinc and cadmium but not by the other divalent ions tested. The zinc/cadmium-dependent stimulation of the reaction increased rapidly and linearly up to a concentration of 0.1 mM and was even further increased at 0.5 mM. At pH 6, the activity was three times higher than at physiological pH. Alteration of the NADPH : NADP(+) ratio revealed that the reaction is inhibited by higher concentrations of the oxidized cofactors. FAD reduced ubiquinone in a dose-dependent manner at a considerably lower rate, suggesting that the reduction of ubiquinone by lipoamide dehydrogenase involves the FAD moiety of the enzyme.     

The mobilization of ferritin iron by liver cytosol. A comparison of xanthine and NADH as reducing substrates.

Considerable evidence suggests that the release of iron from ferritin is a reductive process. A role in this process has been proposed for two hepatic enzymes, namely xanthine oxidoreductase and an NADH oxidoreductase. The abilities of xanthine and NADH to serve as a source of reducing power for the enzyme-mediated release of ferritin iron (ferrireductase activity) were compared with turkey liver and rat liver homogenates. The maximal velocity (Vmax.) for the reaction with NADH was 50 times greater than with xanthine; however, the substrate concentration required to achieve half-maximal velocity (Km) was 1000 times less with xanthine than with NADH. NADPH could be substituted for NADH with little loss in activity. Dicoumarol did not inhibit the reaction with NADH or NADPH, demonstrating that the ferrireductase activity with those substrates was not the result of the liver enzyme 'DT-diaphorase' [NAD(P)H dehydrogenase (quinone)]. A flavin nucleotide was required for ferrireductase activity with rat and turkey liver cytosol when xanthine, NADH or NADPH was used as the reducing substrate. FMN yielded twice the activity with NADH or NADPH, whereas FAD was twice as effective with xanthine as substrate. Kinetic comparisons, differences in lability and partial chromatographic resolution of the ferrireductase activities with the two types of reducing substrates strongly indicate that the ferrireductase activities with xanthine and NADH are catalysed by separate enzyme systems contained in liver cytosol. Complete inhibition by allopurinol of the ferrireductase activity endogenous to undialysed liver cytosol preparations and the ability of xanthine to restore equivalent activity to dialysed preparations indicate that the source of reducing power for the endogenous activity is xanthine. These studies suggest that xanthine, NADH or NADPH can serve as a source of reducing power for the enzyme-mediated reduction of ferritin iron, with a flavin nucleotide serving as the shuttle of electrons from the enzymes to the ferritin iron.     

Zinc is a potent inhibitor of thiol oxidoreductase activity and stimulates reactive oxygen species production by lipoamide dehydrogenase.

Submicromolar zinc inhibits alpha-ketoglutarate-dependent mitochondrial respiration. This was attributed to inhibition of the alpha-ketoglutarate dehydrogenase complex (Brown, A. M., Kristal, B. S., Effron, M. S., Shestopalov, A. I., Ullucci, P. A., Sheu, K.-F. R., Blass, J. P., and Cooper, A. J. L. (2000) J. Biol. Chem. 275, 13441-13447). Lipoamide dehydrogenase, a component of the alpha-ketoglutarate dehydrogenase complex and two other mitochondrial complexes, catalyzes the transfer of reducing equivalents from the bound dihydrolipoate of the neighboring dihydrolipoamide acyltransferase subunit to NAD(+). This reversible reaction involves two reaction centers: a thiol pair, which accepts electrons from dihydrolipoate, and a non-covalently bound FAD moiety, which transfers electrons to NAD(+). The lipoamide dehydrogenase reaction catalyzed by the purified pig heart enzyme is strongly inhibited by Zn(2+) (K(i) approximately 0.15 microm) in both directions. Steady-state kinetic studies revealed that Zn(2+) competes with oxidized lipoamide for the two-electron-reduced enzyme. Interaction of Zn(2+) with the two-electron-reduced enzyme was directly detected in anaerobic stopped-flow experiments. Lipoamide dehydrogenase also catalyzes NADH oxidation by oxygen, yielding hydrogen peroxide as the major product and superoxide radical as a minor product. Zn(2+) accelerates the oxidase reaction up to 5-fold with an activation constant of 0.09 +/- 0.02 microm. Activation is a consequence of Zn(2+) binding to the reduced catalytic thiols, which prevents delocalization of the reducing equivalents between catalytic disulfide and FAD. A kinetic scheme that satisfactorily describes the observed effects has been developed and applied to determine a number of enzyme kinetic parameters in the oxidase reaction. The distinct effects of Zn(2+) on different LADH activities represent a novel example of a reversible switch in enzyme specificity that is modulated by metal ion binding. These results suggest that Zn(2+) can interfere with mitochondrial antioxidant production and may also stimulate production of reactive oxygen species by a novel mechanism.     

Lipid peroxidation, iron mobilization and radical generation induced by alcohol

Increasing evidence points to a major role for free radicals in the pathogenesis of alcohol-induced liver injury. In vitro, free radicals may be generated during ethanol metabolism by the further metabolism of acetaldehyde by molybdenum-dependent oxidases such as xanthine oxidase. Ferritin iron mobilized by such free radicals may serve as catalytic iron. Increased stores of ferritin iron and induction of microsomal P-450 reductase activity are mechanisms by which chronic alcohol feeding may potentiate the acute effects of alcohol.     

Roles of phosphate and an enoyl radical in ferritin iron mobilization by 5-aminolevulinic acid

5-Aminolevulinic acid (ALA), a heme precursor that accumulates in acute intermittent porphyria (AIP) and lead poisoning, undergoes enolization and subsequent iron-catalyzed oxidation at neutral pH. Iron is released from horse spleen ferritin (HoSF) by both ALA-generated O₂^•− and enoyl radical (ALA√), which amplifies the chain of ALA oxidation (autocatalysis). Iron chelators such as EDTA, ATP, but not citrate, and phosphate accelerate this process and ALA-promoted iron release from HoSF is faster in horse spleen isoferritins containing larger amounts of phosphate in the core. ALA (+0.377 V versus standard hydrogen electrode) is less effective in releasing iron from ferritin than are thioglycollic acid, 6-hydroxydopamine, and N,N,N′,N′-tetramethyl-p-phenylenediamine. During electrochemical one electron oxidation of ALA in a nitrogen atmosphere, spin trapping experiments with 3,5-dibromo-4-nitrosobenzenesulfonic acid demonstrated the formation of a spin adduct characterized by a six line signal, indicating a secondary carbon-centered radical and attributed to a resonant ALA√ radical. Iron is also released in such anaerobic electrochemical oxidations of ALA in the presence of ferritin, suggesting that, in addition to O₂^•−, ALA√ can promote iron mobilization from ferritin. Hence, ALA√ may amplify the metal-catalyzed oxidation of ALA, damaging ALA-accumulating cells and possibly contributing to the symptoms of porphyria.     

Methimazole and generation of oxygen radicals by monocytes: potential role in immunosuppression.

A study was conducted investigating the possibility that the immunosuppressive action of methimazole (the active metabolite of the antithyroid drug carbimazole) might be due to an effect on the production of oxygen radicals by monocytes. Techniques comprised measurement of luminol dependent chemoluminescence in monocytes and a spectrophotometric assay for production of hydrogen peroxide. The results showed definite inhibition of formation of oxygen radicals by resting and stimulated monocytes, which may explain the immunosuppressive action of the drug in Graves'' disease. The findings also suggest that the formation of oxygen radicals and the initiation of the immune response may be closely related.     

Reductive release of iron from ferritin by cation free radicals of paraquat and other bipyridyls

NADPH-cytochrome P-450 reductase-catalyzed reduction of paraquat promoted the release of iron from ferritin. Aerobically, iron release was inhibited approximately 60% by superoxide dismutase, whereas xanthine oxidase-dependent iron release was inhibited nearly 100%. This suggests that both superoxide and the paraquat cation radical can catalyze the release of iron from ferritin. Accordingly, under anaerobic conditions, the paraquat radical mediated a very rapid, complete release of iron from ferritin. Similarly, the cation free radicals of the closely related chemicals, diquat and benzyl viologen, also promoted iron release. ESR studies demonstrated that electron transfer from the paraquat cation radical to ferritin accounts for the reductive release of iron. The ferritin structure was not altered by exposure to the paraquat radical and also retained its ability to re-incorporate iron. These studies indicate that release of iron from ferritin may be a common feature contributing to free radical-mediated toxicities.     

Release of iron from ferritin by semiquinone, anthracycline, bipyridyl, and nitroaromatic radicals

The cytotoxicity of many xenobiotics is related to their ability to undergo redox reactions and iron dependent free radical reactions. We have measured the ability of a number of redox active compounds to release iron from the cellular iron storage protein, ferritin. Compounds were reduced to their corresponding radicals with xanthine oxidase/hypoxanthine under N₂ and the release of Fe²⁺ was monitored by complexation with ferrozine. Ferritin iron was released by a number of bipyridyl radicals including those derived from diquat and paraquat, the anthracycline radicals of adriamycin, daunorubicin and epirubicin, the semiquinones of anthraquinone-2-sulphonate, 1,5 and 2,6-dihydroxyanthraquinone, 1-hydroxyanthraquinone, purpurin, and plumbagin, and the nitroaromatic radicals of nitrofurantoin and metronidazole. In each case, iron release was more efficient than with an equivalent flux of superoxide. Introduction of air decreased the rate of iron release, presumably because the organic radicals reacted with O₂ to form superoxide. In air, iron release was inhibited by superoxide dismutase. Semiquinones of menadione, benzoquinone, duroquinone, anthraquinone 1,5 and 2,6-disulphonate, 1,4 naphthoquinone-2-sulphonate and naphthoquinone, when formed under N₂, were unable to release ferrin iron. In air, these systems gave low rates of superoxide dismutase-inhibitible iron release. Of the compounds investigated, those with a single electron reduction potential less than that of ferritin were able to release ferritin iron.     

Effect of oxygen concentration on microsomal oxidation of ethanol and generation of oxygen radicals.

The iron-catalysed production of hydroxyl radicals, by rat liver microsomes (microsomal fractions), assessed by the oxidation of substrate scavengers and ethanol, displayed a biphasic response to the concentration of O2 (varied from 3 to 70%), reaching a maximal value with 20% O2. The decreased rates of hydroxyl-radical generation at lower O2 concentrations correlates with lower rates of production of H2O2, the precursor of hydroxyl radical, whereas the decreased rates at elevated O2 concentrations correlate with lower rates (relative to 20% O2) of activity of NADPH-cytochrome P-450 reductase, which reduces iron and is responsible for redox cycling of iron by the microsomes. The oxidation of aniline or aminopyrine and the cytochrome P-450/oxygen-radical-independent oxidation of ethanol also displayed a biphasic response to the concentration of O2, reaching a maximum at 20% O2, which correlates with the dithionite-reducible CO-binding spectra of cytochrome P-450. Microsomal lipid peroxidation increased as the concentration of O2 was raised from 3 to 7 to 20% O2, and then began to level off. This different pattern of malondialdehyde generation compared with hydroxyl-radical production probably reflects the lack of a role for hydroxyl radical in microsomal lipid peroxidation. These results point to the complex role for O2 in microsomal generation of oxygen radicals, which is due in part to the critical necessity for maintaining the redox state of autoxidizable components of the reaction system.